Ejemplo n.º 1
0
        /// <summary>
        /// Actually computes the insertion. In some cases we would like more info
        /// coming back than we get by using Generate() api. Note that resulting
        /// mesh is *not* compacted.
        /// </summary>
        public DMesh3 ComputeResult(out MeshInsertPolygon insertion)
        {
            AxisAlignedBox2d bounds  = Polygon.Bounds;
            double           padding = 0.1 * bounds.DiagonalLength;

            bounds.Expand(padding);

            TrivialRectGenerator rectgen = (Subdivisions == 1) ?
                                           new TrivialRectGenerator() : new GriddedRectGenerator()
            {
                EdgeVertices = Subdivisions
            };

            rectgen.Width      = (float)bounds.Width;
            rectgen.Height     = (float)bounds.Height;
            rectgen.IndicesMap = new Index2i(1, 2);
            rectgen.UVMode     = UVMode;
            rectgen.Clockwise  = true;              // MeshPolygonInserter assumes mesh faces are CW? (except code says CCW...)
            rectgen.Generate();
            var base_mesh = new DMesh3();

            rectgen.MakeMesh(base_mesh);

            var      shiftPolygon = new GeneralPolygon2d(Polygon);
            Vector2d shift        = bounds.Center;

            shiftPolygon.Translate(-shift);

            var insert = new MeshInsertPolygon()
            {
                Mesh    = base_mesh,
                Polygon = shiftPolygon
            };
            bool bOK = insert.Insert();

            if (!bOK)
            {
                throw new Exception("TriangulatedPolygonGenerator: failed to Insert()");
            }

            MeshFaceSelection selected = insert.InteriorTriangles;
            var editor = new MeshEditor(base_mesh);

            editor.RemoveTriangles((tid) => { return(selected.IsSelected(tid) == false); }, true);

            var shift3 = new Vector3d(shift.x, shift.y, 0);

            MeshTransforms.Translate(base_mesh, shift3);

            insertion = insert;
            return(base_mesh);
        }
Ejemplo n.º 2
0
        public bool Fill()
        {
            compute_polygon();

            // translate/scale fill loops to unit box. This will improve
            // accuracy in the calcs below...
            Vector2d shiftOrigin = Bounds.Center;
            double   scale       = 1.0 / Bounds.MaxDim;

            SpansPoly.Translate(-shiftOrigin);
            SpansPoly.Scale(scale * Vector2d.One, Vector2d.Zero);

            var ElemToLoopMap = new Dictionary <PlanarComplex.Element, int>();

            // generate planar mesh that we will insert polygons into
            MeshGenerator meshgen;
            float         planeW     = 1.5f;
            int           nDivisions = 0;

            if (FillTargetEdgeLen < double.MaxValue && FillTargetEdgeLen > 0)
            {
                int n = (int)((planeW / (float)scale) / FillTargetEdgeLen) + 1;
                nDivisions = (n <= 1) ? 0 : n;
            }

            if (nDivisions == 0)
            {
                meshgen = new TrivialRectGenerator()
                {
                    IndicesMap = new Index2i(1, 2),
                    Width      = planeW,
                    Height     = planeW,
                };
            }
            else
            {
                meshgen = new GriddedRectGenerator()
                {
                    IndicesMap   = new Index2i(1, 2),
                    Width        = planeW,
                    Height       = planeW,
                    EdgeVertices = nDivisions
                };
            }
            DMesh3 FillMesh = meshgen.Generate().MakeDMesh();

            FillMesh.ReverseOrientation();               // why?!?

            int[] polyVertices = null;

            // insert each poly
            var insert = new MeshInsertUVPolyCurve(FillMesh, SpansPoly);
            ValidationStatus status = insert.Validate(MathUtil.ZeroTolerancef * scale);
            bool             failed = true;

            if (status == ValidationStatus.Ok)
            {
                if (insert.Apply())
                {
                    insert.Simplify();
                    polyVertices = insert.CurveVertices;
                    failed       = false;
                }
            }
            if (failed)
            {
                return(false);
            }

            // remove any triangles not contained in gpoly
            // [TODO] degenerate triangle handling? may be 'on' edge of gpoly...
            var removeT = new List <int>();

            foreach (int tid in FillMesh.TriangleIndices())
            {
                Vector3d v = FillMesh.GetTriCentroid(tid);
                if (SpansPoly.Contains(v.xy) == false)
                {
                    removeT.Add(tid);
                }
            }
            foreach (int tid in removeT)
            {
                FillMesh.RemoveTriangle(tid, true, false);
            }

            //Util.WriteDebugMesh(FillMesh, "c:\\scratch\\CLIPPED_MESH.obj");

            // transform fill mesh back to 3d
            MeshTransforms.PerVertexTransform(FillMesh, (v) =>
            {
                Vector2d v2 = v.xy;
                v2         /= scale;
                v2         += shiftOrigin;
                return(to3D(v2));
            });


            //Util.WriteDebugMesh(FillMesh, "c:\\scratch\\PLANAR_MESH_WITH_LOOPS.obj");
            //Util.WriteDebugMesh(MeshEditor.Combine(FillMesh, Mesh), "c:\\scratch\\FILLED_MESH.obj");

            // figure out map between new mesh and original edge loops
            // [TODO] if # of verts is different, we can still find correspondence, it is just harder
            // [TODO] should check that edges (ie sequential verts) are boundary edges on fill mesh
            //    if not, can try to delete nbr tris to repair
            var mergeMapV = new IndexMap(true);

            if (MergeFillBoundary && polyVertices != null)
            {
                throw new NotImplementedException("PlanarSpansFiller: merge fill boundary not implemented!");

                //int[] fillLoopVerts = polyVertices;
                //int NV = fillLoopVerts.Length;

                //PlanarComplex.Element sourceElem = (pi == 0) ? gsolid.Outer : gsolid.Holes[pi - 1];
                //int loopi = ElemToLoopMap[sourceElem];
                //EdgeLoop sourceLoop = Loops[loopi].edgeLoop;

                //for (int k = 0; k < NV; ++k) {
                //    Vector3d fillV = FillMesh.GetVertex(fillLoopVerts[k]);
                //    Vector3d sourceV = Mesh.GetVertex(sourceLoop.Vertices[k]);
                //    if (fillV.Distance(sourceV) < MathUtil.ZeroTolerancef)
                //        mergeMapV[fillLoopVerts[k]] = sourceLoop.Vertices[k];
                //}
            }

            // append this fill to input mesh
            var editor = new MeshEditor(Mesh);

            int[] mapV;
            editor.AppendMesh(FillMesh, mergeMapV, out mapV, Mesh.AllocateTriangleGroup());

            // [TODO] should verify that we actually merged the loops...

            return(true);
        }
        public bool Fill()
        {
            compute_polygons();

            // translate/scale fill loops to unit box. This will improve
            // accuracy in the calcs below...
            Vector2d shiftOrigin = Bounds.Center;
            double   scale       = 1.0 / Bounds.MaxDim;

            foreach (var floop in Loops)
            {
                floop.poly.Translate(-shiftOrigin);
                floop.poly.Scale(scale * Vector2d.One, Vector2d.Zero);
            }

            Dictionary <PlanarComplex.Element, int> ElemToLoopMap = new Dictionary <PlanarComplex.Element, int>();

            // [TODO] if we have multiple components in input mesh, we could do this per-component.
            // This also helps avoid nested shells creating holes.
            // *However*, we shouldn't *have* to because FindSolidRegions will do the right thing if
            // the polygons have the same orientation

            // add all loops to planar complex
            PlanarComplex complex = new PlanarComplex();

            for (int i = 0; i < Loops.Count; ++i)
            {
                var elem = complex.Add(Loops[i].poly);
                ElemToLoopMap[elem] = i;
            }

            // sort into separate 2d solids
            PlanarComplex.SolidRegionInfo solids =
                complex.FindSolidRegions(PlanarComplex.FindSolidsOptions.SortPolygons);

            // fill each 2d solid
            List <Index2i> failed_inserts = new List <Index2i>();
            List <Index2i> failed_merges  = new List <Index2i>();

            for (int fi = 0; fi < solids.Polygons.Count; ++fi)
            {
                var gpoly = solids.Polygons[fi];
                PlanarComplex.GeneralSolid gsolid = solids.PolygonsSources[fi];

                // [TODO] could do scale/translate here, per-polygon would be more precise

                // generate planar mesh that we will insert polygons into
                MeshGenerator meshgen;
                float         planeW     = 1.5f;
                int           nDivisions = 0;
                if (FillTargetEdgeLen < double.MaxValue && FillTargetEdgeLen > 0)
                {
                    int n = (int)((planeW / (float)scale) / FillTargetEdgeLen) + 1;
                    nDivisions = (n <= 1) ? 0 : n;
                }

                if (nDivisions == 0)
                {
                    meshgen = new TrivialRectGenerator()
                    {
                        IndicesMap = new Index2i(1, 2), Width = planeW, Height = planeW,
                    };
                }
                else
                {
                    meshgen = new GriddedRectGenerator()
                    {
                        IndicesMap   = new Index2i(1, 2), Width = planeW, Height = planeW,
                        EdgeVertices = nDivisions
                    };
                }
                DMesh3 FillMesh = meshgen.Generate().MakeDMesh();
                FillMesh.ReverseOrientation();   // why?!?

                // convenient list
                List <Polygon2d> polys = new List <Polygon2d>()
                {
                    gpoly.Outer
                };
                polys.AddRange(gpoly.Holes);

                // for each poly, we track the set of vertices inserted into mesh
                int[][] polyVertices = new int[polys.Count][];

                // insert each poly
                for (int pi = 0; pi < polys.Count; ++pi)
                {
                    MeshInsertUVPolyCurve insert = new MeshInsertUVPolyCurve(FillMesh, polys[pi]);
                    ValidationStatus      status = insert.Validate(MathUtil.ZeroTolerancef * scale);
                    bool failed = true;
                    if (status == ValidationStatus.Ok)
                    {
                        if (insert.Apply())
                        {
                            insert.Simplify();
                            polyVertices[pi] = insert.CurveVertices;
                            failed           = (insert.Loops.Count != 1) ||
                                               (insert.Loops[0].VertexCount != polys[pi].VertexCount);
                        }
                    }
                    if (failed)
                    {
                        failed_inserts.Add(new Index2i(fi, pi));
                    }
                }

                // remove any triangles not contained in gpoly
                // [TODO] degenerate triangle handling? may be 'on' edge of gpoly...
                List <int> removeT = new List <int>();
                foreach (int tid in FillMesh.TriangleIndices())
                {
                    Vector3d v = FillMesh.GetTriCentroid(tid);
                    if (gpoly.Contains(v.xy) == false)
                    {
                        removeT.Add(tid);
                    }
                }
                foreach (int tid in removeT)
                {
                    FillMesh.RemoveTriangle(tid, true, false);
                }

                //Util.WriteDebugMesh(FillMesh, "c:\\scratch\\CLIPPED_MESH.obj");

                // transform fill mesh back to 3d
                MeshTransforms.PerVertexTransform(FillMesh, (v) => {
                    Vector2d v2 = v.xy;
                    v2         /= scale;
                    v2         += shiftOrigin;
                    return(to3D(v2));
                });


                //Util.WriteDebugMesh(FillMesh, "c:\\scratch\\PLANAR_MESH_WITH_LOOPS.obj");
                //Util.WriteDebugMesh(MeshEditor.Combine(FillMesh, Mesh), "c:\\scratch\\FILLED_MESH.obj");

                // figure out map between new mesh and original edge loops
                // [TODO] if # of verts is different, we can still find correspondence, it is just harder
                // [TODO] should check that edges (ie sequential verts) are boundary edges on fill mesh
                //    if not, can try to delete nbr tris to repair
                IndexMap mergeMapV = new IndexMap(true);
                if (MergeFillBoundary)
                {
                    for (int pi = 0; pi < polys.Count; ++pi)
                    {
                        if (polyVertices[pi] == null)
                        {
                            continue;
                        }
                        int[] fillLoopVerts = polyVertices[pi];
                        int   NV            = fillLoopVerts.Length;

                        PlanarComplex.Element sourceElem = (pi == 0) ? gsolid.Outer : gsolid.Holes[pi - 1];
                        int      loopi      = ElemToLoopMap[sourceElem];
                        EdgeLoop sourceLoop = Loops[loopi].edgeLoop;

                        if (sourceLoop.VertexCount != NV)
                        {
                            failed_merges.Add(new Index2i(fi, pi));
                            continue;
                        }

                        for (int k = 0; k < NV; ++k)
                        {
                            Vector3d fillV   = FillMesh.GetVertex(fillLoopVerts[k]);
                            Vector3d sourceV = Mesh.GetVertex(sourceLoop.Vertices[k]);
                            if (fillV.Distance(sourceV) < MathUtil.ZeroTolerancef)
                            {
                                mergeMapV[fillLoopVerts[k]] = sourceLoop.Vertices[k];
                            }
                        }
                    }
                }

                // append this fill to input mesh
                MeshEditor editor = new MeshEditor(Mesh);
                int[]      mapV;
                editor.AppendMesh(FillMesh, mergeMapV, out mapV, Mesh.AllocateTriangleGroup());

                // [TODO] should verify that we actually merged the loops...
            }

            if (failed_inserts.Count > 0 || failed_merges.Count > 0)
            {
                return(false);
            }

            return(true);
        }